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/* -----------------------------------------------------------------------------
* pycontainer.swg
*
* Python sequence <-> C++ container wrapper
*
* This wrapper, and its iterator, allows a general use (and reuse) of
* the mapping between C++ and Python, thanks to the C++ templates.
*
* Of course, it needs the C++ compiler to support templates, but
* since we will use this wrapper with the STL containers, that should
* be the case.
* ----------------------------------------------------------------------------- */
%{
#include <iostream>
#if PY_VERSION_HEX >= 0x03020000
# define SWIGPY_SLICE_ARG(obj) ((PyObject*) (obj))
#else
# define SWIGPY_SLICE_ARG(obj) ((PySliceObject*) (obj))
#endif
%}
#if !defined(SWIG_NO_EXPORT_ITERATOR_METHODS)
# if !defined(SWIG_EXPORT_ITERATOR_METHODS)
# define SWIG_EXPORT_ITERATOR_METHODS SWIG_EXPORT_ITERATOR_METHODS
# endif
#endif
%include <pyiterators.swg>
/**** The PySequence C++ Wrap ***/
%fragment("<stdexcept>");
%include <std_except.i>
%fragment("container_owner_attribute_init", "init") {
// thread safe initialization
swig::container_owner_attribute();
}
%fragment("reference_container_owner", "header", fragment="container_owner_attribute_init") {
namespace swig {
static PyObject* container_owner_attribute() {
static PyObject* attr = SWIG_Python_str_FromChar("__swig_container");
return attr;
}
template <typename T>
struct container_owner {
// By default, do not add the back-reference (for value types)
// Specialization below will check the reference for pointer types.
static bool back_reference(PyObject* child, PyObject* owner) {
return false;
}
};
template <>
struct container_owner<swig::pointer_category> {
/*
* Call to add a back-reference to the owning object when returning a
* reference from a container. Will only set the reference if child
* is a SWIG wrapper object that does not own the pointer.
*
* returns whether the reference was set or not
*/
static bool back_reference(PyObject* child, PyObject* owner) {
SwigPyObject* swigThis = SWIG_Python_GetSwigThis(child);
if (swigThis && (swigThis->own & SWIG_POINTER_OWN) != SWIG_POINTER_OWN) {
PyObject_SetAttr(child, container_owner_attribute(), owner);
return true;
}
return false;
}
};
}
}
%fragment(SWIG_Traits_frag(swig::SwigPtr_PyObject),"header",fragment="StdTraits") {
namespace swig {
template <> struct traits<SwigPtr_PyObject > {
typedef value_category category;
static const char* type_name() { return "SwigPtr_PyObject"; }
};
template <> struct traits_from<SwigPtr_PyObject> {
typedef SwigPtr_PyObject value_type;
static PyObject *from(const value_type& val) {
PyObject *obj = static_cast<PyObject *>(val);
Py_XINCREF(obj);
return obj;
}
};
template <>
struct traits_check<SwigPtr_PyObject, value_category> {
static bool check(SwigPtr_PyObject) {
return true;
}
};
template <> struct traits_asval<SwigPtr_PyObject > {
typedef SwigPtr_PyObject value_type;
static int asval(PyObject *obj, value_type *val) {
if (val) *val = obj;
return SWIG_OK;
}
};
}
}
%fragment(SWIG_Traits_frag(swig::SwigVar_PyObject),"header",fragment="StdTraits") {
namespace swig {
template <> struct traits<SwigVar_PyObject > {
typedef value_category category;
static const char* type_name() { return "SwigVar_PyObject"; }
};
template <> struct traits_from<SwigVar_PyObject> {
typedef SwigVar_PyObject value_type;
static PyObject *from(const value_type& val) {
PyObject *obj = static_cast<PyObject *>(val);
Py_XINCREF(obj);
return obj;
}
};
template <>
struct traits_check<SwigVar_PyObject, value_category> {
static bool check(SwigVar_PyObject) {
return true;
}
};
template <> struct traits_asval<SwigVar_PyObject > {
typedef SwigVar_PyObject value_type;
static int asval(PyObject *obj, value_type *val) {
if (val) *val = obj;
return SWIG_OK;
}
};
}
}
%fragment("SwigPySequence_Base","header",fragment="<stddef.h>",fragment="StdTraits")
{
%#include <functional>
namespace std {
template <>
struct less <PyObject *>
{
bool
operator()(PyObject * v, PyObject *w) const
{
bool res;
SWIG_PYTHON_THREAD_BEGIN_BLOCK;
res = PyObject_RichCompareBool(v, w, Py_LT) ? true : false;
/* This may fall into a case of inconsistent
eg. ObjA > ObjX > ObjB
but ObjA < ObjB
*/
if( PyErr_Occurred() && PyErr_ExceptionMatches(PyExc_TypeError) )
{
/* Objects can't be compared, this mostly occurred in Python 3.0 */
/* Compare their ptr directly for a workaround */
res = (v < w);
PyErr_Clear();
}
SWIG_PYTHON_THREAD_END_BLOCK;
return res;
}
};
template <>
struct less <swig::SwigPtr_PyObject>
{
bool
operator()(const swig::SwigPtr_PyObject& v, const swig::SwigPtr_PyObject& w) const
{
return std::less<PyObject *>()(v, w);
}
};
template <>
struct less <swig::SwigVar_PyObject>
{
bool
operator()(const swig::SwigVar_PyObject& v, const swig::SwigVar_PyObject& w) const
{
return std::less<PyObject *>()(v, w);
}
};
}
namespace swig {
template <> struct traits<PyObject *> {
typedef value_category category;
static const char* type_name() { return "PyObject *"; }
};
template <> struct traits_asval<PyObject * > {
typedef PyObject * value_type;
static int asval(PyObject *obj, value_type *val) {
if (val) *val = obj;
return SWIG_OK;
}
};
template <>
struct traits_check<PyObject *, value_category> {
static bool check(PyObject *) {
return true;
}
};
template <> struct traits_from<PyObject *> {
typedef PyObject * value_type;
static PyObject *from(const value_type& val) {
Py_XINCREF(val);
return val;
}
};
}
namespace swig {
template <class Difference>
inline size_t
check_index(Difference i, size_t size, bool insert = false) {
if ( i < 0 ) {
if ((size_t) (-i) <= size)
return (size_t) (i + size);
} else if ( (size_t) i < size ) {
return (size_t) i;
} else if (insert && ((size_t) i == size)) {
return size;
}
throw std::out_of_range("index out of range");
}
template <class Difference>
void
slice_adjust(Difference i, Difference j, Py_ssize_t step, size_t size, Difference &ii, Difference &jj, bool insert = false) {
if (step == 0) {
throw std::invalid_argument("slice step cannot be zero");
} else if (step > 0) {
// Required range: 0 <= i < size, 0 <= j < size, i <= j
if (i < 0) {
ii = 0;
} else if (i < (Difference)size) {
ii = i;
} else if (insert && (i >= (Difference)size)) {
ii = (Difference)size;
}
if (j < 0) {
jj = 0;
} else {
jj = (j < (Difference)size) ? j : (Difference)size;
}
if (jj < ii)
jj = ii;
} else {
// Required range: -1 <= i < size-1, -1 <= j < size-1, i >= j
if (i < -1) {
ii = -1;
} else if (i < (Difference) size) {
ii = i;
} else if (i >= (Difference)(size-1)) {
ii = (Difference)(size-1);
}
if (j < -1) {
jj = -1;
} else {
jj = (j < (Difference)size ) ? j : (Difference)(size-1);
}
if (ii < jj)
ii = jj;
}
}
template <class Sequence, class Difference>
inline typename Sequence::iterator
getpos(Sequence* self, Difference i) {
typename Sequence::iterator pos = self->begin();
std::advance(pos, check_index(i,self->size()));
return pos;
}
template <class Sequence, class Difference>
inline typename Sequence::const_iterator
cgetpos(const Sequence* self, Difference i) {
typename Sequence::const_iterator pos = self->begin();
std::advance(pos, check_index(i,self->size()));
return pos;
}
template <class Sequence>
inline void
erase(Sequence* seq, const typename Sequence::iterator& position) {
seq->erase(position);
}
template <class Sequence>
struct traits_reserve {
static void reserve(Sequence & /*seq*/, typename Sequence::size_type /*n*/) {
// This should be specialized for types that support reserve
}
};
template <class Sequence, class Difference>
inline Sequence*
getslice(const Sequence* self, Difference i, Difference j, Py_ssize_t step) {
typename Sequence::size_type size = self->size();
Difference ii = 0;
Difference jj = 0;
swig::slice_adjust(i, j, step, size, ii, jj);
if (step > 0) {
typename Sequence::const_iterator sb = self->begin();
typename Sequence::const_iterator se = self->begin();
std::advance(sb,ii);
std::advance(se,jj);
if (step == 1) {
return new Sequence(sb, se);
} else {
Sequence *sequence = new Sequence();
swig::traits_reserve<Sequence>::reserve(*sequence, (jj - ii + step - 1) / step);
typename Sequence::const_iterator it = sb;
while (it!=se) {
sequence->push_back(*it);
for (Py_ssize_t c=0; c<step && it!=se; ++c)
it++;
}
return sequence;
}
} else {
Sequence *sequence = new Sequence();
swig::traits_reserve<Sequence>::reserve(*sequence, (ii - jj - step - 1) / -step);
typename Sequence::const_reverse_iterator sb = self->rbegin();
typename Sequence::const_reverse_iterator se = self->rbegin();
std::advance(sb,size-ii-1);
std::advance(se,size-jj-1);
typename Sequence::const_reverse_iterator it = sb;
while (it!=se) {
sequence->push_back(*it);
for (Py_ssize_t c=0; c<-step && it!=se; ++c)
it++;
}
return sequence;
}
}
template <class Sequence, class Difference, class InputSeq>
inline void
setslice(Sequence* self, Difference i, Difference j, Py_ssize_t step, const InputSeq& is = InputSeq()) {
typename Sequence::size_type size = self->size();
Difference ii = 0;
Difference jj = 0;
swig::slice_adjust(i, j, step, size, ii, jj, true);
if (step > 0) {
if (step == 1) {
size_t ssize = jj - ii;
if (ssize <= is.size()) {
// expanding/staying the same size
swig::traits_reserve<Sequence>::reserve(*self, self->size() - ssize + is.size());
typename Sequence::iterator sb = self->begin();
typename InputSeq::const_iterator isit = is.begin();
std::advance(sb,ii);
std::advance(isit, jj - ii);
self->insert(std::copy(is.begin(), isit, sb), isit, is.end());
} else {
// shrinking
typename Sequence::iterator sb = self->begin();
typename Sequence::iterator se = self->begin();
std::advance(sb,ii);
std::advance(se,jj);
self->erase(sb,se);
sb = self->begin();
std::advance(sb,ii);
self->insert(sb, is.begin(), is.end());
}
} else {
size_t replacecount = (jj - ii + step - 1) / step;
if (is.size() != replacecount) {
char msg[1024];
sprintf(msg, "attempt to assign sequence of size %lu to extended slice of size %lu", (unsigned long)is.size(), (unsigned long)replacecount);
throw std::invalid_argument(msg);
}
typename Sequence::const_iterator isit = is.begin();
typename Sequence::iterator it = self->begin();
std::advance(it,ii);
for (size_t rc=0; rc<replacecount && it != self->end(); ++rc) {
*it++ = *isit++;
for (Py_ssize_t c=0; c<(step-1) && it != self->end(); ++c)
it++;
}
}
} else {
size_t replacecount = (ii - jj - step - 1) / -step;
if (is.size() != replacecount) {
char msg[1024];
sprintf(msg, "attempt to assign sequence of size %lu to extended slice of size %lu", (unsigned long)is.size(), (unsigned long)replacecount);
throw std::invalid_argument(msg);
}
typename Sequence::const_iterator isit = is.begin();
typename Sequence::reverse_iterator it = self->rbegin();
std::advance(it,size-ii-1);
for (size_t rc=0; rc<replacecount && it != self->rend(); ++rc) {
*it++ = *isit++;
for (Py_ssize_t c=0; c<(-step-1) && it != self->rend(); ++c)
it++;
}
}
}
template <class Sequence, class Difference>
inline void
delslice(Sequence* self, Difference i, Difference j, Py_ssize_t step) {
typename Sequence::size_type size = self->size();
Difference ii = 0;
Difference jj = 0;
swig::slice_adjust(i, j, step, size, ii, jj, true);
if (step > 0) {
typename Sequence::iterator sb = self->begin();
std::advance(sb,ii);
if (step == 1) {
typename Sequence::iterator se = self->begin();
std::advance(se,jj);
self->erase(sb,se);
} else {
typename Sequence::iterator it = sb;
size_t delcount = (jj - ii + step - 1) / step;
while (delcount) {
it = self->erase(it);
for (Py_ssize_t c=0; c<(step-1) && it != self->end(); ++c)
it++;
delcount--;
}
}
} else {
typename Sequence::reverse_iterator sb = self->rbegin();
std::advance(sb,size-ii-1);
typename Sequence::reverse_iterator it = sb;
size_t delcount = (ii - jj - step - 1) / -step;
while (delcount) {
it = typename Sequence::reverse_iterator(self->erase((++it).base()));
for (Py_ssize_t c=0; c<(-step-1) && it != self->rend(); ++c)
it++;
delcount--;
}
}
}
}
}
%fragment("SwigPySequence_Cont","header",
fragment="StdTraits",
fragment="SwigPySequence_Base",
fragment="SwigPyIterator_T")
{
namespace swig
{
template <class T>
struct SwigPySequence_Ref
{
SwigPySequence_Ref(PyObject* seq, Py_ssize_t index)
: _seq(seq), _index(index)
{
}
operator T () const
{
swig::SwigVar_PyObject item = PySequence_GetItem(_seq, _index);
try {
return swig::as<T>(item);
} catch (const std::invalid_argument& e) {
char msg[1024];
sprintf(msg, "in sequence element %d ", (int)_index);
if (!PyErr_Occurred()) {
::%type_error(swig::type_name<T>());
}
SWIG_Python_AddErrorMsg(msg);
SWIG_Python_AddErrorMsg(e.what());
throw;
}
}
SwigPySequence_Ref& operator=(const T& v)
{
PySequence_SetItem(_seq, _index, swig::from<T>(v));
return *this;
}
private:
PyObject* _seq;
Py_ssize_t _index;
};
template <class T>
struct SwigPySequence_ArrowProxy
{
SwigPySequence_ArrowProxy(const T& x): m_value(x) {}
const T* operator->() const { return &m_value; }
operator const T*() const { return &m_value; }
T m_value;
};
template <class T, class Reference >
struct SwigPySequence_InputIterator
{
typedef SwigPySequence_InputIterator<T, Reference > self;
typedef std::random_access_iterator_tag iterator_category;
typedef Reference reference;
typedef T value_type;
typedef T* pointer;
typedef Py_ssize_t difference_type;
SwigPySequence_InputIterator()
{
}
SwigPySequence_InputIterator(PyObject* seq, Py_ssize_t index)
: _seq(seq), _index(index)
{
}
reference operator*() const
{
return reference(_seq, _index);
}
SwigPySequence_ArrowProxy<T>
operator->() const {
return SwigPySequence_ArrowProxy<T>(operator*());
}
bool operator==(const self& ri) const
{
return (_index == ri._index) && (_seq == ri._seq);
}
bool operator!=(const self& ri) const
{
return !(operator==(ri));
}
self& operator ++ ()
{
++_index;
return *this;
}
self& operator -- ()
{
--_index;
return *this;
}
self& operator += (difference_type n)
{
_index += n;
return *this;
}
self operator +(difference_type n) const
{
return self(_seq, _index + n);
}
self& operator -= (difference_type n)
{
_index -= n;
return *this;
}
self operator -(difference_type n) const
{
return self(_seq, _index - n);
}
difference_type operator - (const self& ri) const
{
return _index - ri._index;
}
bool operator < (const self& ri) const
{
return _index < ri._index;
}
reference
operator[](difference_type n) const
{
return reference(_seq, _index + n);
}
private:
PyObject* _seq;
difference_type _index;
};
// STL container wrapper around a Python sequence
template <class T>
struct SwigPySequence_Cont
{
typedef SwigPySequence_Ref<T> reference;
typedef const SwigPySequence_Ref<T> const_reference;
typedef T value_type;
typedef T* pointer;
typedef Py_ssize_t difference_type;
typedef size_t size_type;
typedef const pointer const_pointer;
typedef SwigPySequence_InputIterator<T, reference> iterator;
typedef SwigPySequence_InputIterator<T, const_reference> const_iterator;
SwigPySequence_Cont(PyObject* seq) : _seq(0)
{
if (!PySequence_Check(seq)) {
throw std::invalid_argument("a sequence is expected");
}
_seq = seq;
Py_INCREF(_seq);
}
~SwigPySequence_Cont()
{
Py_XDECREF(_seq);
}
size_type size() const
{
return static_cast<size_type>(PySequence_Size(_seq));
}
bool empty() const
{
return size() == 0;
}
iterator begin()
{
return iterator(_seq, 0);
}
const_iterator begin() const
{
return const_iterator(_seq, 0);
}
iterator end()
{
return iterator(_seq, size());
}
const_iterator end() const
{
return const_iterator(_seq, size());
}
reference operator[](difference_type n)
{
return reference(_seq, n);
}
const_reference operator[](difference_type n) const
{
return const_reference(_seq, n);
}
bool check() const
{
Py_ssize_t s = size();
for (Py_ssize_t i = 0; i < s; ++i) {
swig::SwigVar_PyObject item = PySequence_GetItem(_seq, i);
if (!swig::check<value_type>(item))
return false;
}
return true;
}
private:
PyObject* _seq;
};
}
}
%define %swig_sequence_iterator(Sequence...)
%swig_sequence_iterator_with_making_function(swig::make_output_iterator,Sequence...)
%enddef
%define %swig_sequence_forward_iterator(Sequence...)
%swig_sequence_iterator_with_making_function(swig::make_output_forward_iterator,Sequence...)
%enddef
%define %swig_sequence_iterator_with_making_function(Make_output_iterator,Sequence...)
#if defined(SWIG_EXPORT_ITERATOR_METHODS)
class iterator;
class reverse_iterator;
class const_iterator;
class const_reverse_iterator;
%typemap(out,noblock=1,fragment="SwigPySequence_Cont")
iterator, reverse_iterator, const_iterator, const_reverse_iterator {
$result = SWIG_NewPointerObj(Make_output_iterator(%static_cast($1,const $type &)),
swig::SwigPyIterator::descriptor(),SWIG_POINTER_OWN);
}
%typemap(out,noblock=1,fragment="SwigPySequence_Cont")
std::pair<iterator, iterator>, std::pair<const_iterator, const_iterator> {
$result = PyTuple_New(2);
PyTuple_SetItem($result,0,SWIG_NewPointerObj(Make_output_iterator(%static_cast($1,const $type &).first),
swig::SwigPyIterator::descriptor(),SWIG_POINTER_OWN));
PyTuple_SetItem($result,1,SWIG_NewPointerObj(Make_output_iterator(%static_cast($1,const $type &).second),
swig::SwigPyIterator::descriptor(),SWIG_POINTER_OWN));
}
%fragment("SwigPyPairBoolOutputIterator","header",fragment=SWIG_From_frag(bool),fragment="SwigPySequence_Cont") {}
%typemap(out,noblock=1,fragment="SwigPyPairBoolOutputIterator")
std::pair<iterator, bool>, std::pair<const_iterator, bool> {
$result = PyTuple_New(2);
PyTuple_SetItem($result,0,SWIG_NewPointerObj(Make_output_iterator(%static_cast($1,const $type &).first),
swig::SwigPyIterator::descriptor(),SWIG_POINTER_OWN));
PyTuple_SetItem($result,1,SWIG_From(bool)(%static_cast($1,const $type &).second));
}
%typemap(in,noblock=1,fragment="SwigPySequence_Cont")
iterator(swig::SwigPyIterator *iter = 0, int res),
reverse_iterator(swig::SwigPyIterator *iter = 0, int res),
const_iterator(swig::SwigPyIterator *iter = 0, int res),
const_reverse_iterator(swig::SwigPyIterator *iter = 0, int res) {
res = SWIG_ConvertPtr($input, %as_voidptrptr(&iter), swig::SwigPyIterator::descriptor(), 0);
if (!SWIG_IsOK(res) || !iter) {
%argument_fail(SWIG_TypeError, "$type", $symname, $argnum);
} else {
swig::SwigPyIterator_T<$type > *iter_t = dynamic_cast<swig::SwigPyIterator_T<$type > *>(iter);
if (iter_t) {
$1 = iter_t->get_current();
} else {
%argument_fail(SWIG_TypeError, "$type", $symname, $argnum);
}
}
}
%typecheck(%checkcode(ITERATOR),noblock=1,fragment="SwigPySequence_Cont")
iterator, reverse_iterator, const_iterator, const_reverse_iterator {
swig::SwigPyIterator *iter = 0;
int res = SWIG_ConvertPtr($input, %as_voidptrptr(&iter), swig::SwigPyIterator::descriptor(), 0);
$1 = (SWIG_IsOK(res) && iter && (dynamic_cast<swig::SwigPyIterator_T<$type > *>(iter) != 0));
}
%fragment("SwigPySequence_Cont");
%newobject iterator(PyObject **PYTHON_SELF);
%extend {
swig::SwigPyIterator* iterator(PyObject **PYTHON_SELF) {
return Make_output_iterator(self->begin(), self->begin(), self->end(), *PYTHON_SELF);
}
#if defined(SWIGPYTHON_BUILTIN)
%feature("python:slot", "tp_iter", functype="getiterfunc") iterator;
#else
%pythoncode %{def __iter__(self):
return self.iterator()%}
#endif
}
#endif //SWIG_EXPORT_ITERATOR_METHODS
%enddef
/**** The python container methods ****/
%define %swig_container_methods(Container...)
/* deprecated in Python 2 */
#if 1
%newobject __getslice__;
#endif
%newobject __getitem__(PySliceObject *slice);
#if defined(SWIGPYTHON_BUILTIN)
%feature("python:slot", "nb_nonzero", functype="inquiry") __nonzero__;
%feature("python:slot", "sq_length", functype="lenfunc") __len__;
#endif // SWIGPYTHON_BUILTIN
%extend {
bool __nonzero__() const {
return !(self->empty());
}
/* Alias for Python 3 compatibility */
bool __bool__() const {
return !(self->empty());
}
size_type __len__() const {
return self->size();
}
// Although __getitem__, front, back actually use a const value_type& return type, the typemaps below
// use non-const so that they can be easily overridden by users if necessary.
%typemap(ret, fragment="reference_container_owner", noblock=1) value_type& __getitem__, value_type& front, value_type& back {
(void)swig::container_owner<swig::traits<$*1_ltype>::category>::back_reference($result, $self);
}
}
%enddef
%define %swig_sequence_methods_common(Sequence...)
%swig_sequence_iterator(%arg(Sequence))
%swig_container_methods(%arg(Sequence))
%fragment("SwigPySequence_Base");
#if defined(SWIGPYTHON_BUILTIN)
//%feature("python:slot", "sq_item", functype="ssizeargfunc") __getitem__;
//%feature("python:slot", "sq_slice", functype="ssizessizeargfunc") __getslice__;
//%feature("python:slot", "sq_ass_item", functype="ssizeobjargproc") __setitem__;
//%feature("python:slot", "sq_ass_slice", functype="ssizessizeobjargproc") __setslice__;
%feature("python:slot", "mp_subscript", functype="binaryfunc") __getitem__;
%feature("python:slot", "mp_ass_subscript", functype="objobjargproc") __setitem__;
#endif // SWIGPYTHON_BUILTIN
%extend {
/* typemap for slice object support */
%typemap(in) PySliceObject* {
if (!PySlice_Check($input)) {
%argument_fail(SWIG_TypeError, "$type", $symname, $argnum);
}
$1 = (PySliceObject *) $input;
}
%typemap(typecheck,precedence=SWIG_TYPECHECK_POINTER) PySliceObject* {
$1 = PySlice_Check($input);
}
/* deprecated in Python 2 */
#if 1
Sequence* __getslice__(difference_type i, difference_type j) throw (std::out_of_range, std::invalid_argument) {
return swig::getslice(self, i, j, 1);
}
void __setslice__(difference_type i, difference_type j) throw (std::out_of_range, std::invalid_argument) {
swig::setslice(self, i, j, 1, Sequence());
}
void __setslice__(difference_type i, difference_type j, const Sequence& v) throw (std::out_of_range, std::invalid_argument) {
swig::setslice(self, i, j, 1, v);
}
void __delslice__(difference_type i, difference_type j) throw (std::out_of_range, std::invalid_argument) {
swig::delslice(self, i, j, 1);
}
#endif
void __delitem__(difference_type i) throw (std::out_of_range, std::invalid_argument) {
swig::erase(self, swig::getpos(self, i));
}
/* Overloaded methods for Python 3 compatibility
* (Also useful in Python 2.x)
*/
Sequence* __getitem__(PySliceObject *slice) throw (std::out_of_range, std::invalid_argument) {
Py_ssize_t i, j, step;
if( !PySlice_Check(slice) ) {
SWIG_Error(SWIG_TypeError, "Slice object expected.");
return NULL;
}
PySlice_GetIndices(SWIGPY_SLICE_ARG(slice), (Py_ssize_t)self->size(), &i, &j, &step);
Sequence::difference_type id = i;
Sequence::difference_type jd = j;
return swig::getslice(self, id, jd, step);
}
void __setitem__(PySliceObject *slice, const Sequence& v) throw (std::out_of_range, std::invalid_argument) {
Py_ssize_t i, j, step;
if( !PySlice_Check(slice) ) {
SWIG_Error(SWIG_TypeError, "Slice object expected.");
return;
}
PySlice_GetIndices(SWIGPY_SLICE_ARG(slice), (Py_ssize_t)self->size(), &i, &j, &step);
Sequence::difference_type id = i;
Sequence::difference_type jd = j;
swig::setslice(self, id, jd, step, v);
}
void __setitem__(PySliceObject *slice) throw (std::out_of_range, std::invalid_argument) {
Py_ssize_t i, j, step;
if( !PySlice_Check(slice) ) {
SWIG_Error(SWIG_TypeError, "Slice object expected.");
return;
}
PySlice_GetIndices(SWIGPY_SLICE_ARG(slice), (Py_ssize_t)self->size(), &i, &j, &step);
Sequence::difference_type id = i;
Sequence::difference_type jd = j;
swig::delslice(self, id, jd, step);
}
void __delitem__(PySliceObject *slice) throw (std::out_of_range, std::invalid_argument) {
Py_ssize_t i, j, step;
if( !PySlice_Check(slice) ) {
SWIG_Error(SWIG_TypeError, "Slice object expected.");
return;
}
PySlice_GetIndices(SWIGPY_SLICE_ARG(slice), (Py_ssize_t)self->size(), &i, &j, &step);
Sequence::difference_type id = i;
Sequence::difference_type jd = j;
swig::delslice(self, id, jd, step);
}
}
%enddef
%define %swig_sequence_methods_non_resizable(Sequence...)
%swig_sequence_methods_common(%arg(Sequence))
%extend {
const value_type& __getitem__(difference_type i) const throw (std::out_of_range) {
return *(swig::cgetpos(self, i));
}
void __setitem__(difference_type i, const value_type& x) throw (std::out_of_range) {
*(swig::getpos(self,i)) = x;
}
#if defined(SWIGPYTHON_BUILTIN)
// This will be called through the mp_ass_subscript slot to delete an entry.
void __setitem__(difference_type i) throw (std::out_of_range, std::invalid_argument) {
swig::erase(self, swig::getpos(self, i));
}
#endif
}
%enddef
%define %swig_sequence_methods(Sequence...)
%swig_sequence_methods_non_resizable(%arg(Sequence))
%extend {
value_type pop() throw (std::out_of_range) {
if (self->size() == 0)
throw std::out_of_range("pop from empty container");
Sequence::value_type x = self->back();
self->pop_back();
return x;
}
void append(const value_type& x) {
self->push_back(x);
}
}
%enddef
%define %swig_sequence_methods_non_resizable_val(Sequence...)
%swig_sequence_methods_common(%arg(Sequence))
%extend {
value_type __getitem__(difference_type i) throw (std::out_of_range) {
return *(swig::cgetpos(self, i));
}
void __setitem__(difference_type i, value_type x) throw (std::out_of_range) {
*(swig::getpos(self,i)) = x;
}
#if defined(SWIGPYTHON_BUILTIN)
// This will be called through the mp_ass_subscript slot to delete an entry.
void __setitem__(difference_type i) throw (std::out_of_range, std::invalid_argument) {
swig::erase(self, swig::getpos(self, i));
}
#endif
}
%enddef
%define %swig_sequence_methods_val(Sequence...)
%swig_sequence_methods_non_resizable_val(%arg(Sequence))
%extend {
value_type pop() throw (std::out_of_range) {
if (self->size() == 0)
throw std::out_of_range("pop from empty container");
Sequence::value_type x = self->back();
self->pop_back();
return x;
}
void append(value_type x) {
self->push_back(x);
}
}
%enddef
//
// Common fragments
//
%fragment("StdSequenceTraits","header",
fragment="StdTraits",
fragment="SwigPySequence_Cont")
{
namespace swig {
template <class SwigPySeq, class Seq>
inline void
assign(const SwigPySeq& swigpyseq, Seq* seq) {
// seq->assign(swigpyseq.begin(), swigpyseq.end()); // not used as not always implemented
typedef typename SwigPySeq::value_type value_type;
typename SwigPySeq::const_iterator it = swigpyseq.begin();
for (;it != swigpyseq.end(); ++it) {
seq->insert(seq->end(),(value_type)(*it));
}
}
template <class Seq, class T = typename Seq::value_type >
struct traits_asptr_stdseq {
typedef Seq sequence;
typedef T value_type;
static int asptr(PyObject *obj, sequence **seq) {
if (obj == Py_None || SWIG_Python_GetSwigThis(obj)) {
sequence *p;
swig_type_info *descriptor = swig::type_info<sequence>();
if (descriptor && SWIG_IsOK(::SWIG_ConvertPtr(obj, (void **)&p, descriptor, 0))) {
if (seq) *seq = p;
return SWIG_OLDOBJ;
}
} else if (PySequence_Check(obj)) {
try {
SwigPySequence_Cont<value_type> swigpyseq(obj);
if (seq) {
sequence *pseq = new sequence();
assign(swigpyseq, pseq);
*seq = pseq;
return SWIG_NEWOBJ;
} else {
return swigpyseq.check() ? SWIG_OK : SWIG_ERROR;
}
} catch (std::exception& e) {
if (seq) {
if (!PyErr_Occurred()) {
PyErr_SetString(PyExc_TypeError, e.what());
}
}
return SWIG_ERROR;
}
}
return SWIG_ERROR;
}
};
template <class Seq, class T = typename Seq::value_type >
struct traits_from_stdseq {
typedef Seq sequence;
typedef T value_type;
typedef typename Seq::size_type size_type;
typedef typename sequence::const_iterator const_iterator;
static PyObject *from(const sequence& seq) {
%#ifdef SWIG_PYTHON_EXTRA_NATIVE_CONTAINERS
swig_type_info *desc = swig::type_info<sequence>();
if (desc && desc->clientdata) {
return SWIG_InternalNewPointerObj(new sequence(seq), desc, SWIG_POINTER_OWN);
}
%#endif
size_type size = seq.size();
if (size <= (size_type)INT_MAX) {
PyObject *obj = PyTuple_New((Py_ssize_t)size);
Py_ssize_t i = 0;
for (const_iterator it = seq.begin(); it != seq.end(); ++it, ++i) {
PyTuple_SetItem(obj,i,swig::from<value_type>(*it));
}
return obj;
} else {
PyErr_SetString(PyExc_OverflowError,"sequence size not valid in python");
return NULL;
}
}
};
}
}